# Is this Fibonacci sequence function recursive?

``````fib=0:1:zipWith (+) fib (tail fib)
``````

A coworker is trying to assert that this is not a recursive function because `fib` is simply a list that defines itself with itself and that is somehow different than a function that does the same. I think he's smoking crack.

What do you think?

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printf "Oh no, a function with zero arguments, we can't have that!" or die; –  Thomas M. DuBuisson Oct 20 '10 at 17:57
A `fib` indeed. –  Ani Oct 20 '10 at 17:58
`zipWith` is the recursive function, and `fib` refers to its result. There's nothing magical or non-recursive about it. (The answers below that claim there "is no function" are as confused as your coworker.) –  Piet Delport Oct 20 '10 at 18:10
Your coworker friend is picking nits. It's technically a recursively defined value, not a function. –  pelotom Oct 20 '10 at 18:26
Piet, your definitions are non-standard. Don't assume everyone's wrong because they're all using the same definitions, which happen to not match yours. –  Carl Oct 20 '10 at 20:00

The fibonacci definition with zipWith is not a recursive function, in fact there is no function involved, fib is a list (data) that is lazily self-defined, utilizing Haskell's lazy semantic. In a sense, you can call it recursive list or recursive data; but not recursive function.

It may be difficult to wrap your head around recursive list since very little programming languages have anything close, but you'll notice that in Haskell all functions takes exactly one paramater. `fib` does not take any parameter, because it's not a function. Since there is no function involved, you can't have recursive function.

Your coworker isn't smoking crack, he's enlightened (or smoking crack, if that's your definition of enlightenment).

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@Piet Delport: `fib` appears on the right hand side of its own definition.... what word do you use for that? I call that "recursive". Neither the recursiveness nor functionalness (functionality?) of `zipWith` is being called into question here. –  pelotom Oct 20 '10 at 18:45
pelotom: In Haskell, there is a fundamental difference between recursive data and recursive functions. Recursive data is when a data structure concretely refers back to its own constructors, as happens when you say `xs = 1:2:3:xs`: the final cons refers back to the initial one, forming a cycle. There are many different ways to achieve this kind of data recursion: see Tying the Knot. Recursive functions, on the other hand, are like `zipWith`. They may or may not define recursive data structures, too, but in this case, `fib` is not. –  Piet Delport Oct 20 '10 at 19:27
@Piet: `xs = 1:2:3:xs` is a self-referential definition, as is `fib=0:1:zipWith (+) fib (tail fib)`. they're both recursive data. What's the problem? –  pelotom Oct 20 '10 at 19:31
@Piet: the fact that `fib` makes use of `zipWith` in its definition is neither here nor there. `fib` is most certainly recursive data, as attested to by the fact that it is defined in terms of itself. See those 2 instances of `fib` on the RHS of the equation? That means it's defined in terms of itself, e.g. it is recursive. I don't know how many different ways I can restate this basic point. –  pelotom Oct 20 '10 at 20:08
@Piet Delport: Recursive data is data that is defined with reference to itself; a recursive data has the general form of: `recd = a1 : a2 : ... : an : (f recd)`. The case of `xs = 1 : 2 : 3 : xs` is only a special case when `f x = x`. Therefore `fib` is a recursive data when `f x = zipWith (+) x (tail x)`. That `f` internally uses a recursive function (e.g. `zipWith`) is totally irrelevant. –  Lie Ryan Oct 21 '10 at 23:17

My, what a rat's nest of subtle terminological distinctions. What is "this"?

``````fib=0:1:zipWith (+) fib (tail fib)
``````

It is not a recursive function. It is not recursive data. It is a recursive definition.

What is being defined?

``````fib
``````

What type of thing is `fib`, according to this definition?

``````[Integer]
``````

A list of integers (or perhaps a list of any old numeric stuff).

Is `fib` a function? No, it is a list. Is `fib` recursively defined? Yes. Would `fib` be recursively defined if we replaced `zipWith` by a nonrecursive function of the same type (e.g. `\ f xs ys -> xs`)? Yes, although it would be a different recursively defined list.

Is `fib` a cyclic list? No. Does "recursive data structure" mean "cyclic data structure"? Not according to Hoare's paper, "Recursive Data Structures": http://portal.acm.org/book_gateway.cfm?id=63445&type=pdf&bookpath=%2F70000%2F63445%2Fcb-p217-hoare.pdf&coll=&dl=&CFID=15151515&CFTOKEN=6184618

In a typed setting, "recursive data structure" means no more or less than "inhabitant of a recursively defined type". Correspondingly `"fred"` is a recursive data structure, even though it is not recursively defined, and indeed it can be acted upon by recursive functions such as `++`.

The phrase "recursive function" means "recursively defined function". The phrase "recursive value" means "recursively defined value", such as exist in nonstrict languages: strict languages have the "value recursion" problem.

And if you think that's pedantic, try defining `fib` that way in a total programming language, and you'll discover that the notion of "recursive definition" splits into "definition by structural recursion" (consuming data in a way which stops) and "definition by guarded corecursion" (producing data in a way which goes), and that `fib` is of the latter variety. In that setting, the productivity of `fib` depends crucially on the laziness of `zipWith`. In the Haskell setting, of course, you don't need to worry about any of that stuff to figure out what sort of definition something is, just to figure out whether it has half a chance of actually working.

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It's recursive. You can tell because the name on the LHS of the `=` also appears on the RHS.

It is however not a function. You can tell because the type of `fib` does not contain a `->`.

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@Piet: But that was not the question. The OP specifically says "this Fibonacci sequence function", so he's clearly not asking about zipWith (unless you're saying zipWith is "Fibonacci sequence function"). –  sepp2k Oct 20 '10 at 18:24
@Piet: But `zipWith (+) fib (tail fib)` is also not a function. `zipWith` is a function, `zipWith (+) fib (tail fib)` is the result of applying that function. –  sepp2k Oct 20 '10 at 18:49
@Piet: Well, fine, but a function application is still not the same as a function. –  sepp2k Oct 20 '10 at 19:23
@Piet: No, it's not besides the point at all. As you said yourself, the question was whether a recursive function is being defined here. Since the only thing being defined here is `fib` and `fib` is not a function, the answer to that is clearly no. –  sepp2k Oct 20 '10 at 19:50
There is definitely somebody being obtuse here. –  pelotom Oct 20 '10 at 20:10

The example you've given is recursive. But the Fibonacci sequence by nature doesn't have to be. There are iterative versions of the algorithm, and even explicit functions.

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Iteration is just a special case of recursion, and generating a sequence will always be recursive in some sense, for hopefully obvious reasons. The formula to compute single terms independently, however, is not itself recursive (although it uses functions that will probably be calculated recursively). –  C. A. McCann Oct 20 '10 at 18:27

He's on crack - the above function is clearly recursive.

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The above is clearly recursive, but it is not a function. –  sepp2k Oct 20 '10 at 18:00
sepp2k: `zipWith` is a function. –  Piet Delport Oct 20 '10 at 18:20
@Piet: The question was whether `fib` was a recursive function, not whether `zipWith` was. –  sepp2k Oct 20 '10 at 18:22
sepp2k: The question was whether "the following code" was a recursive function, and it clearly is. The fact that `fib` only refers to the result of the recursive function is besides the point, and does not change the fact that the body is a recursive function. –  Piet Delport Oct 20 '10 at 18:46

Aside from the Haskell implementation here, the Fibonacci Numbers are a sequence defined by a recurrence relation. Mathematically speaking, each term is defined as a function of the preceding terms. Defeat him with mathematical semantics.

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Although the standard definition is the recurrence relation, any given implementation could use the closed form (even though this one doesn't), so this wouldn't be a sound argument for implementation questions. –  John L Oct 20 '10 at 18:28

For this to be recursive function, it needs to be both recursive and a function. As sepp2k points out, it's clearly recursive because the name `fib` appears on both sides of the `=`. That is, `fib` is defined in terms of itself.

Is it a function? Not according to its type. In haskell, we call a 0-argument function "data". So this definition of `fib` creates a recursive data structure, but not a recursive function.

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`fib` is a not a recursive data structure in this case: "recursive data structure" means something entirely different in Haskell. `fib` is an infinite, non-repeating (and hence non-recursive) data structure generated by a recursive function (`zipWith`). –  Piet Delport Oct 20 '10 at 19:50

Since most answers support your coworker with respect to the function part of: "`fib` is not a recursive function." I'd like to elaborate on on the recursive part Conor McBride hinted at in his answer.

The definition given for `fib` is not recursive, it is co-recursive.

Co-recursion looks a lot like recursion in that, as many posters have pointed out, the LHS of the definition appears on the RHS too. But there is no base case. Recursion and corecursion "run in opposite directions".

The above definition of `fib` starts from the initial values 0 and 1 and moves "up" from there and keeps on going. On the other hand a recursive definition of, say (a function calculating) the n-th Fibonacci number

``````fib' 0 = 0
fib' 1 = 1
fib' n = fib' (n-1) + fib' (n-2)
``````

walks "downwards" from the n-th number until it reaches the base cases and there stops.

I guess this vindicates the crackhead in both points :-)

For further reading check out the wikipedia article on Corecursion and the links there. If you can get you hands on it, Chapter 10 of The Haskell Road to Logic, Maths and Programming by Kees Doets and Jan van Eijck may be worth a peek.

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As for the function/nonfunction argument, in Haskell, from the programmer's point of view, IT DOESN'T MATTER! Because both functions and data structures are evaluated lazily, a value and a function of no arguments returning a value are indistinguishable. What you have is a list of integers, evaluated lazily and recursively. `fib` is simultaneously a "list of integers", a "function of no arguments returning a list of integers", a "list of functions of no arguments returning integers", and "a function of no arguments returning a list of functions of no arguments returning integers".
It honestly does not matter. The language makes no distinction between the four. Type theory makes no distinction between the four (and countless others: a function of no arguments returning any of those is equally valid, as is a function of no arguments returning that, ad infinitum). It honestly makes no difference whether or not you call `fib` a "function" or not.